CN106663843A - Battery sleep mode management method and system - Google Patents
Battery sleep mode management method and system Download PDFInfo
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- CN106663843A CN106663843A CN201580023019.0A CN201580023019A CN106663843A CN 106663843 A CN106663843 A CN 106663843A CN 201580023019 A CN201580023019 A CN 201580023019A CN 106663843 A CN106663843 A CN 106663843A
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- battery
- battery module
- state
- management system
- operational
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/425—Structural combination with electronic components, e.g. electronic circuits integrated to the outside of the casing
- H01M10/4257—Smart batteries, e.g. electronic circuits inside the housing of the cells or batteries
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B11/00—Automatic controllers
- G05B11/01—Automatic controllers electric
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/48—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/48—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte
- H01M10/486—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte for measuring temperature
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/48—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte
- H01M10/488—Cells or batteries combined with indicating means for external visualization of the condition, e.g. by change of colour or of light density
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/425—Structural combination with electronic components, e.g. electronic circuits integrated to the outside of the casing
- H01M2010/4271—Battery management systems including electronic circuits, e.g. control of current or voltage to keep battery in healthy state, cell balancing
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M2220/00—Batteries for particular applications
- H01M2220/20—Batteries in motive systems, e.g. vehicle, ship, plane
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- Engineering & Computer Science (AREA)
- Manufacturing & Machinery (AREA)
- Chemical & Material Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- Electrochemistry (AREA)
- General Chemical & Material Sciences (AREA)
- Microelectronics & Electronic Packaging (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Automation & Control Theory (AREA)
- Secondary Cells (AREA)
- Power Engineering (AREA)
Abstract
A method for managing a battery module includes receiving data relating to one or more operational parameters of the battery module. The method also includes determining whether a first operational parameter of the one or more operational parameters violates a first threshold. Additionally, the method includes transitioning the battery module from an operational mode to a sleep mode in response to a determination that the first operational parameter violates the first threshold.
Description
Background technology
Present invention relates in general to cell apparatus and system, and relate more specifically to Vehicular battery management system.
It is made up of one or more the electrochemistry battery cores for the electric energy that can convert chemical energy into the form for being easier to use
Battery be widely used in it is many industry and application in.For example, many such batteries are to start motorcycle, automobile, card
The starting of the explosive motor of car and other vehicles, illumination and (SLI) battery of lighting a fire.Such battery generally can be
The life cycle of battery is discharged before exhausting in cycles and supplements electric charge.Generally, when terminal use buys new battery
When, for example, in order to be integrated in the vehicle of such as motorcycle, the electricity of battery is unknown.Regrettably, it is being inserted into user
Vehicle in when, if the electricity of battery for example before purchase battery on showing stand during exhausted, battery may
Do not work.In addition, the charging of such battery generally needs for leader cable to be connected to battery terminal, this possibly trouble and
Time-consuming.Accordingly, there exist the demand of the battery system of these shortcomings for overcoming legacy system.
The content of the invention
It relates to a kind of method of management battery module, methods described includes receiving and one of the battery module
Or the data that multiple operational factors are related.Methods described also includes the first operation in the one or more of operational factors of determination
Whether parameter violates first threshold.In addition, methods described is included in response to determining that first operational factor violates described first
The battery module is changed into sleep pattern from operational mode by threshold value.
The disclosure further relates to a kind of system, and the system includes the battery management system being arranged in the housing of battery module
System.The battery management system is configured to one or more operational factors for analyzing the battery module.In addition, the battery
Management system is configured to the analysis at least partly giving the one or more of operational factors to the battery module, by institute
State battery module to change between operational mode and sleep pattern.
The disclosure is additionally related to a kind of system including battery module, and the battery module includes being arranged in the battery mould
Battery management system in the housing of block.The system also includes that the state-of-charge for being configured to be attached to the battery module refers to
Show device.The state-of-charge indicator includes the switch of the manual operation being arranged on the housing of the state-of-charge indicator.
The switch is configured to change between on-state and off state, and the state-of-charge indicator is configured to ring
The state change switched described in Ying Yu transmits a signal to the battery management system.Additionally, the battery management system is matched somebody with somebody
Being set to makes the battery module change between operational mode and sleep pattern in response to received signal.
Description of the drawings
Fig. 1 is the perspective view of the embodiment of the vehicle with battery module, and shows to be attached to battery and be connected to
The state-of-charge indicator of battery charger or maintenance device;
Fig. 2 is the perspective view of the embodiment of the motorcycle with the battery module for being connected to state-of-charge indicator, the lotus
Electricity condition indicator can be connected to battery charger or maintenance device;
Fig. 3 be state-of-charge indicator and including battery management system battery embodiment schematic diagram;
Fig. 4 is the block diagram of the embodiment of the battery including battery management system of Fig. 3;
Fig. 5 is the exploded view of the embodiment of the battery including battery management system of Fig. 3;
Fig. 6 is the perspective view of the embodiment of the state-of-charge indicator of Fig. 3;
Fig. 7 is to represent to be adapted to the logic of the sleep pattern system (regime) of the cells convert of Fig. 3 to sleep pattern
Flow chart;And
Fig. 8 is the logic for representing the wake-up system for being adapted to that the battery of Fig. 3 is converted to operational mode from sleep pattern
Flow chart.
Specific embodiment
Will be described below one or more specific embodiments.In order to provide the simple and clear description to these embodiments, at this
All features of actual embodiment are not described in description.It is to be appreciated that in any such actual embodiment
Research and development in, as the same in any engineering or design object, it is necessary to make many embodiments and specifically determine with reality
The specific objective (the related constraint related to business of such as compliant systems) of existing developer, which may between different embodiments
Have some change.Furthermore, it is to be understood that, such development is probably complicated and time-consuming but public for enjoying
For opening those those of ordinary skill of benefit, this is only the routine mission for designing, manufacture and producing.
When the element of multiple different embodiments of the disclosure is introduced, article "/(a/an) ", and " described " purport
Meaning there are one or more elements.Term " including (comprising) ", " including (including) " and " having " purport
It is being inclusive and is meaning there may be extra element except the element listed.In addition, it will be appreciated that of this disclosure
The reference of " one embodiment " or " embodiment " is not intended to be interpreted to exclude the additional embodiment for also incorporating institute's stated features
Presence.
As described in more detail below, the present embodiment is related to the system and method for battery detection and management.System and
Method can include the battery management system comprising one or more sensors and process circuit.Battery management system can be monitored
The multiple parameters of battery, such as voltage, temperature, electric current and state-of-charge.In addition, battery management system can be by performing
Battery core balances to protect battery.Additionally, by monitoring multiple operational factors of battery and undesirable in response to what is detected
Battery is placed in sleep pattern by operation conditions, and battery management system can be by preventing the independent battery core of battery and/or battery
Overdischarge (for example, under-voltage), input overvoltage, input overcurrent and overheated protecting battery.Battery management system can be wrapped
Include the adapter for being adapted to that state-of-charge indicator is connected to battery management system so that state-of-charge indicator can be provided
The instruction of the state-of-charge of battery.Thus, state-of-charge indicator can be via connector family to battery.State-of-charge indicator
Can also be the interface between battery management system and charging system.In certain embodiments, state-of-charge indicator can be wrapped
Include and be adapted to allow battery is placed in sleep pattern manually and battery (that is, " waking up " from sleep pattern) is reactivated manually
SR (for example, momentary contact switch).
In view of foregoing teachings, Fig. 1 illustrates the battery system 10 including the battery 12 being arranged in vehicle 14.Battery 12
It is commonly used in vehicle, as illustrated, the vehicle can be automobile, truck, ship, motorcycle, recreation vehicle, golf
Car, carriage, off-road vehicle, electric power moving vehicle, electric power water carrier or other vehicles using battery electric power.Although battery
In 12 boots for being shown at vehicle 14 or rear portion, but in other embodiments, the position of battery 12 can be with difference.Example
Such as, can be used together based on the free space in vehicle, the weight balancing of desired vehicle and battery system 10 other
The position of part (for example, chiller etc.) and various other Considerations are selecting the position of battery 12.In some backgrounds
In embodiment, battery may some be difficult to touch, and many aspects of the disclosure allow battery be still it is mounted while
State-of-charge, the sleep pattern of the battery that charges to battery, controls and other operations of battery etc. are checked, so as to touch tired this
These operations are greatly facilitated when difficult.
Battery 12 can be the starting with any desired design, type, voltage and capacity, illumination and light a fire (SLI)
Battery, or battery 12 can be deep cycle battery, this depends on the type of vehicle and application.Additionally, battery can according to appoint
The technology of what currently known or later exploitation designing and construct, such as wet battery core technology, glass mat (glass mat) skill
Art, gel battery core technology etc..In certain embodiments, battery 12 can be lithium ion battery.Further, in some embodiments
In, battery 12 can be only summer using battery and may be unsuitable in the winter time during use.Similarly, when vehicle is only even
When that is used or seasonality is used, described technology permission manages battery and charges with function to adapt to this so selected use
On the way.
Battery 12 includes positive terminal and negative terminal 16, these terminals can be connected to wire harness or vehicle 14 in utilization
The miscellaneous part of the voltage output of battery 12.The present embodiment of battery 12 can also include for multiple external electrical conductors being connected to electricity
The adapter 18 (for example, multi-conductor connector) of the internal part in pond 12, such as female.For example, as illustrated, adapter 18
State-of-charge indicator 20 can be connected to into electricity via the lead 22 of the state-of-charge indicator 20 being arranged in adapter 18
Pond 12.As will be described in more detail below, state-of-charge indicator 20 can from 12 receiving data of battery (such as battery 12
Voltage), and can provide battery 12 state-of-charge instruction.In addition, state-of-charge indicator 20 can be adapted to profit
Battery charger/maintenance device 24 is connected to lead 26.
Once state-of-charge indicator 20 is electrically coupled to charger/maintenance device 24, it is possible to apply charging power by suitable
Sequence passes through lead 26, state-of-charge indicator 20, lead 22 and adapter 18, with the stored charge in battery 12.Battery charges
Other power supplys that device/maintenance device 24 can provide AC electric power from electrical network 28 or to battery system 10 receive electric power.It should be understood that
Be, battery charger/maintenance device 24 can be configured as any desired battery charger being used together with battery 12 or
Battery maintenance device.Battery charger generally provides high charge current to battery 12, so that relatively quickly (for example, in one night) is right
Battery 12 charges, and battery maintenance device generally provides the reduced-current " trickle " of charging power to battery 12.Such as art technology
Personnel are it should be understood that battery charger/maintenance device 24 can be portable, or can have fixed position.Additionally,
Charger/maintenance device can realize any desired charging system, such as based on the voltage of sensing, charged stage, cell voltage
With the system of capacity etc..
Similarly, Fig. 2 illustrates the motorcycle 40 with the battery 12 for being attached to state-of-charge indicator 20.Due to motor
Battery 12 in car 40 (or some other vehicles 14) is likely difficult to touch so that equipment is directly connected to these terminals 16, carries
It is probably desired for state-of-charge indicator 20.State-of-charge indicator 20 can internally be connected to battery via lead 22
12 terminal 16 and adapter 18.Therefore, state-of-charge indicator 20 allows user to read the state-of-charge of battery 12 and right
Battery 12 is charged or safeguards, reaches these terminals 16 without any dismounting.Again, electrical network 28 can be to battery
System 10 provides AC electric power.Such arrangement can be charged when required by being simply inserted into charger/maintenance device 24
Promote battery 12 in positioning indicator 20 to the connection of charger/maintenance device 24.
It should be pointed out that when the connection of these battery terminals is mentioned in the disclosure, in many embodiments, institute
Stating connection actually will be carried out in inside battery.That is, can carry out it is such be connected to adapter, conductor or including
Other points that portion's battery circuit extends to actual outside terminal and extends from actual outside terminal.
Fig. 3 shows the embodiment of the battery system 10 including battery 12, and the battery includes integrated (for example, self-contained)
Battery management system 50.As illustrated, battery 12 includes the array 52 of the battery battery core 54 for being electrically coupled to battery management system 50.
In certain embodiments, battery battery core 54 can be lithium-ion electric core, LiFePO4 battery core, lighium polymer battery core, nickel metallic hydrogen
The electrochemistry battery core of compound battery core or any other suitable type.In addition, battery battery core 54 can have any suitable physics
Configuration, such as prismatic, oval, cylindrical, polygon etc..
In the embodiment shown, these battery battery cores 54 are connected in series via busbar 55.That is, each remittance
Stream bar 55 is connected between the negative terminal 58 of positive terminal 56 and adjacent battery battery core 54 of a battery battery core 54.So
And, it should be appreciated that these battery battery cores 54 can adopt the array configuration for substituting, such as in parallel or include in parallel and go here and there
Any other suitable arrangement of connection configuration.Further, although illustrate four battery battery cores 54 in array 52, but can
With using any appropriate number of battery battery core 54.
In certain embodiments, multiple battery battery cores 54 can be grouped into multiple modules, and multiple modules form array 52.
In such embodiments, the first busbar can be electrically coupled to the positive terminal of each battery battery core 54 in a module
56, and the second busbar can be electrically coupled to the negative terminal 58 of each battery battery core 54 in the module.These remittances
Stream bar further can be electrically coupled to battery management system 50 and be configured to electric power signal is transferred to from battery battery core 54
Battery management system 50.Multiple modules can connect in series and/or in parallel with form array 52 and starting to vehicle 14,
Illumination, ignition part, vehicle propulsion system or some other loads provide desired electric power output.For example, implement at one
In example, battery system 10 can include two modules being connected in parallel, and each module can be including four for being connected in series
Battery battery core 54.Among other functions, battery management system can allow to make these electricity are connected at the point of load balance
Core and from power taking in these battery cores or group, as discussed below.
As described above, battery 12 also includes integrated (for example, self-contained) battery management system 50.In certain embodiments,
Battery management system 50 can include one or more integrated circuits or printed circuit board (PCB), the integrated circuit or printed circuit board (PCB)
Can use from battery battery core 54 including the discreet component being mounted and interconnected on a printed circuit, and battery management system 50
The electric power that receives of array 52 (for example, via regulated power supply) running.In addition, battery management system 50 can be disposed in electricity
In the housing 60 in pond 12.In certain embodiments, battery management system 50 can be disposed in below the lid 62 of battery 12.Example
Such as, battery management system 50 can be mounted to or permanently attached to the inner surface of lid 62.In other embodiments, cell tube
Reason system 50 can be disposed between lid 62 and the array 52 of battery battery core 54.For example, such as below will be with reference to Fig. 5 in more detail
Description, battery management system 50 can be mounted to or permanently attached to propping up above the array 52 of battery battery core 54
Support structure (for example, board mount) so that 50 offset from cover 62 of battery monitoring system and array 52.
As will be described in more detail, battery management system 50 can be adapted to monitor and provide and battery 12
Healthy related feedback.For example, battery management system 50 can be adapted to one or more operational factors for monitoring battery 12,
Such as voltage, temperature or electric current.Additionally, battery management system 50 can provide one or more operational factors with battery 12
Related data.For example, battery management system 50 can provide data (for example to state-of-charge indicator 20 via adapter 18
The state-of-charge of battery 12).In addition, battery management system 50 can (for example, operational factor exceedes the thing of threshold value with recording events
Part), and the data with regard to these events can be supplied to data input/output instrument.Additionally, battery management system 50 can
To perform battery core balance, this can improve the performance of battery 12 and life-span.In addition, in response to detecting adverse events, cell tube
Reason system 50 can protect battery battery core 54 against damages by battery 12 is converted to sleep pattern.For example, as it is following more
Describe in detail, when the voltage or electric current of battery 12 drop below predeterminated level, or in response to indicating from state-of-charge
The sleep signal that device 20 is received, battery management system 50 can force battery 12 to enter sleep pattern.
In order to monitor battery 12, battery management system 50 can be adapted to the array 52 from monitoring battery battery core 54
One or more parameters battery core measurement electronic installation receive signal.For example, measurement apparatus 64 can with array 52 in it is every
Individual battery battery core 54 is associated per Battery pack battery core 54, and can be adapted to 50 output signal of battery monitoring system.
As shown in Fig. 3, measurement apparatus 64 can be mounted to the outer surface 66 of each battery battery core 54.In certain embodiments,
Measurement apparatus 64 can be one or more sensors (for example, thermocouple, voltmeter, ammeter etc.).In other embodiments,
Measurement apparatus 64 can be the printed circuit board (PCB) for including one or more sensors (for example, thermocouple, voltmeter, ammeter etc.)
Or integrated circuit.
Although the embodiment for being shown includes the measurement apparatus 64 of the outer surface 66 for being installed to each battery battery core 54, should
When, it is noted that in other embodiments, these measurement apparatus 64 can be by permanently attached to corresponding outer surface 66, installation
To or be otherwise attach to the inner surface of each battery battery core 54 or suitable arranged arranging with any other.Such as
Shown in figure, each measurement apparatus 64 include being connected to the positive terminal 56 of corresponding battery battery core 54 the first lead 68, and
It is connected to the second lead 70 of the negative terminal 58 of corresponding battery battery core 54.Therefore, each measurement apparatus 64 can be communicatedly
It is connected to battery monitoring system 50.Additionally, in other embodiments, these measurement apparatus 64 can be arranged on battery management system
Sensor (for example, being arranged in the sensor on the printed circuit board (PCB) of battery management system 50) on system, and these measurement dresses
Put the lead of 64 terminals 56 and 58 that can include each measurement apparatus 64 is connected to corresponding battery battery core 54.Therefore, survey
Amount device 64 can be associated with corresponding battery battery core 54, but be not mounted directly or be attached to corresponding battery battery core 54.
In certain embodiments, battery system 10 can include being installed to the measurement apparatus 64 of multiple battery battery cores 54 and be arranged in electricity
In pond management system 50 and it is adapted to corresponding with the monitoring of 58 lead via the terminal 56 for being connected to corresponding battery battery core 54
Battery battery core 54 operational factor measurement apparatus 64 combination.
Fig. 4 is the schematic diagram of the embodiment of the battery system 10 for including battery management system 50 and measurement apparatus 64.As schemed
Shown, measurement apparatus 64 can include the voltmeter 90 for being electrically coupled to the first lead 68 and the second lead 70.Because the first lead
68 are electrically coupled to positive terminal 56 and the second lead 70 is electrically coupled to negative terminal 58, and voltmeter 90 will measurement battery electricity
The voltage at 54 two ends of core.In the embodiment shown, voltmeter 90 is also electrically coupled to microprocessor 92.However, should refer to
Go out, when microprocessor is mentioned in this discussion, can adopt any suitable process circuit.Microprocessor 92 can be received
Signal from voltmeter 90, battery management is transferred to based on the signal of change voltage for receiving and by the voltage for calculating
System 50.For example, in certain embodiments, voltmeter 90 can export the analogue signal proportional to measured voltage.It is micro-
Processor 92 can convert analog signals into digital signal, and can determine voltage based on the digital signal.However, should
When, it is noted that in certain embodiments, measurement apparatus 64 can not include microprocessor 92 or process circuit.In such reality
Apply in example, voltmeter 90 can export analogue signal to battery management system 50, and the battery management system can be adapted to
Voltage is determined using the signal for receiving.Especially, battery management system 50 can include microprocessor 94 or can be configured to
Receive the signal from voltmeter 90 and other suitable process circuits of voltage are determined based on the signal for receiving.
As illustrated, measurement apparatus 64 can also include thermocouple 96.Thermocouple 96 can be communicably coupled to microprocessor
The microprocessor 94 of device 92 (if present) and battery management system 50.As measurement apparatus 64 can be with battery battery core 54
Inner surface or outer surface directly contact, thermocouple is by the signal of output indication battery battery core temperature.Therefore, microprocessor 92
And/or microprocessor 94 can determine battery core temperature based on the signal.For example, in certain embodiments, thermocouple 96 can be with
Export the analogue signal with measured temperature proportional.In such embodiments, microprocessor 92 and/or microprocessor 94
Can be configured to convert analog signals into digital signal and based on the digital signal temperature.
In addition, measurement apparatus 64 can also include ammeter 98.Ammeter 98 can be communicably coupled to microprocessor 92
(if present) and battery management system 50 microprocessor 94.Therefore, microprocessor 92 and/or microprocessor 94 can be with
The electric current of battery battery core 54 is determined based on the signal.For example, in certain embodiments, ammeter 98 can export with it is measured
Current in proportion analogue signal.In such embodiments, microprocessor 92 and/or microprocessor 94 can be configured to
Convert analog signals into digital signal and electric current is determined based on the digital signal.
Although the embodiment for being shown of measurement apparatus 64 includes voltmeter 90, thermocouple 96, and ammeter 98, should
When, it is noted that alternate embodiment can include the additional sensing of other operational factors for being configured to monitor battery battery core 54
Device.For example, in certain embodiments, measurement apparatus 54 can include the ratio for being adapted to measure the electrolyte in battery battery core 54
The sensor of weight or pH levels, the sensor are determined for the state-of-charge of battery 12.In a further embodiment,
Measurement apparatus 64 including being configured to detect the pressure transducer of the pressure in battery battery core 54, ohmmeter or can be configured to
Any other suitable sensor of the electricity of monitoring battery battery core 54, physically or chemically parameter.Additionally, in some embodiments
In, measurement apparatus 64 can also include the memorizer for being communicably coupled to microprocessor 90, and the memorizer can be stored and electricity
The relevant information of pond battery core 54 and/or it is used for calculating the algorithm of these different operational factors by microprocessor 90.
Additionally, in certain embodiments, battery management system 50 can include the battle array for being adapted to measure battery battery core 54
One or more sensors of the operational factor of row 52.As illustrated, battery management system 50 can include voltmeter 100 and electricity
Flow table 102, the voltmeter and ammeter are communicably coupled to microprocessor 94 and are adapted to measure array 52 respectively
Total voltage and electric current.In addition, battery management system 50 can include the thermocouple 104 for being communicably coupled to microprocessor 94,
The thermocouple is adapted to the temperature of the one or more battery battery core 54 for measuring array 52.It will be further noted that
It is that battery 12 can include electricity, any suitable sensor of physically or chemically parameter for being configured to monitor battery 12.Example
Such as, in certain embodiments, battery 12 can include being adapted to be measured from charger/maintenance device 24 respectively being transferred to battery 12
Input voltage and electric current additional voltmeter and ammeter.
Although here mentions some sensors of " table (meter) " form, but it should keeping firmly in mind, the actual biography for being used
Sensor can include or can not include the reader certain form of " table " such as routine.That is, " table " (sensing
Device) inside of battery and management system can be fully located at.
Microprocessor 94 can be configured to one or more operational factors for calculating battery battery core 54 and/or battery 12.
For example, as described above, microprocessor 94 can receive from voltmeter 90, thermocouple 96, and ammeter 98 signal, and
Can be based on the parameter of these the signal of change such as voltage of battery battery core 54, temperature and the electric currents that receive.In addition, microprocessor
Device 94 can calculate voltage, the electric current of battery 12 respectively based on the signal from voltmeter 100, ammeter 102 and thermocouple 104
And temperature.For example, microprocessor 94 can be based on from one or more 100 Hes of voltmeter being arranged on battery management system 50
The signal that ammeter 102 is received is calculating from battery battery core 54 voltage and current of the electric power of the terminal 16 for flowing to battery 12.
In certain embodiments, battery management system 50 be configured to detect and calculate each 54 two ends of single battery battery core, with
And the voltage difference at 52 two ends of whole array of battery battery core 54.This can enable battery management system 50 perform electricity as needed
Core is balanced.
Battery management system 50 can include memorizer 106, and the memorizer can be stored for calculating battery battery core 54
Instruction and/or algorithm with the operational factor of battery 12.Additionally, in certain embodiments, memorizer 106 can store these fortune
The threshold value of line parameter, such as maximum temperature of battery 12, the maximum temperature of battery battery core 54, the minimum voltage of battery 12, electric current
And/or state-of-charge, and the minimum voltage of battery battery core 54, electric current and/or state-of-charge.Therefore, microprocessor 94 can be with
It is configured to access memorizer 106 to read the data stored in memorizer 106.
Further, microprocessor 94 can be configured to the state-of-charge for calculating battery 12.Microprocessor 94 can be by
It is configured so that any suitable signal (such as from the voltmeter 90 for one or more battery battery core 54, from battery
The voltmeter 100 of management system 50, from for one or more battery battery core 54 ammeter 98, and/or from cell tube
The signal of the ammeter 102 of reason system 50) or signal combination calculating the state-of-charge of battery 12.In certain embodiments,
Microprocessor 94 can be configured to discharge rate (for example, the electric discharge song for being based at least partially on the voltage of battery 12, battery 12
Line), and battery 12 temperature calculating the state-of-charge of battery 12.It should be pointed out that can use from one or many
The letter of the signal of the voltmeter 90 of individual battery battery core 54 and/or one or more voltmeters 100 from battery management system 50
Number determining the voltage of battery 12.It is likewise possible to using the signal of the thermocouple 96 from one or more battery battery core 54
And/or from battery management system 50 thermocouple 104 signal determining the temperature of battery 12.However, it should be understood that
Memorizer 106 can be stored and can be accessed in order to calculate the information of state-of-charge by microprocessor 94, such as one or more calculations
The discharge rate of method and battery 12.
Microprocessor 94 can communicate with providing the state-of-charge for calculating of battery 12 with state-of-charge indicator 20
Indicate.As it is indicated above, it is probably desired that state-of-charge indicator 20 is provided as mooring device, because can hold
Change places assessment state-of-charge, without dismantling vehicle to touch battery 12.Additionally, in certain embodiments, in vehicle (example
Such as, motorcycle) in battery 12 be likely difficult to touch or reach, and be tethered at state-of-charge indicator 20 for a user than electricity
Pond 12 is easier to touch.
In certain embodiments, state-of-charge indicator 20 can be visual detector, for example one or more luminous two
Pole pipe (LED), with the color corresponding to the state-of-charge of battery 12, (for example, red expression is discharged shape to the visual detector
State, green represent that full of electricity condition yellow represents part charged state) illuminate.For example, in certain embodiments, if battery
12 state-of-charge is higher than first threshold, then microprocessor 94 can send to state-of-charge indicator 20 and cause state-of-charge to refer to
Show that device 20 provides the first signal for indicating (for example, green LED).In addition, if the state-of-charge of battery 12 is less than Second Threshold,
Then microprocessor 94 can send to state-of-charge indicator 20 and cause the second instruction of state-of-charge indicator offer (for example, red
Color LED) signal.Further, in certain embodiments, if the state-of-charge of battery 12 in the first and second threshold values it
Between, then microprocessor 94 can send to state-of-charge indicator 20 and cause state-of-charge indicator 20 to provide the 3rd instruction (example
Such as, yellow led) signal.
In another embodiment, state-of-charge indicator 20 can be configured as showing and current electric quantity and restriction battery
Capacity always may the ratio corresponding percentage ratio of electricity visually indicate panel.Although the embodiment for being shown is related to charged
Positioning indicator 20, it should be understood that the outut device of any suitable type (for example, audio frequency and/or video frequency output set
It is standby) can be used for providing a user with the feedback related to battery 12.Further, it is to be noted that by state-of-charge indicator 20
Or the feedback that any other suitable output device is provided is not limited to state-of-charge.For example, in other embodiments, output device
The feedback related to the temperature of battery 12 or some other desired parameters can be provided.
As it is indicated above, between state-of-charge indicator 20 or battery 12 and battery charger/maintenance device 24
Interface.Using state-of-charge indicator 20 as the interface for being connected to charger/maintenance device 24 be probably it is desired, because
State-of-charge indicator 20 can more easily be touched than the terminal 16 of battery 12 for user.Generally, battery charger can be with one
Needed for night charges to battery 12, and battery maintenance device within the longer time period can be charged, and/or be simply maintained to battery
State-of-charge.For example, battery maintenance device can be used for the electric charge of the battery for maintaining electric power moving vehicle, the electric power sport(s) car
May discharge between craticular stage.Charger/maintenance device 24 can include power conversion circuit, to produce suitable for battery
Any mode needed for 12 outputs charged is changed or adjusts the electric power from the entrance of electrical network 26.In addition, in certain embodiments, fill
Electrical equipment/maintenance device 24 can include charging control circuit, be conveyed with the electric charge that battery 12 is monitored and controlled.In some embodiments
In, charger/maintenance device 24 can receive data from battery management system 50 via state-of-charge indicator 20, for example electricity
The state-of-charge in pond 12, and the charging control circuit of charger/maintenance device 24 can be controlled using the data for receiving it is right
The electric charge conveying of battery 12.In other embodiments, battery management system 50 can monitor the state-of-charge and Jing of battery 12
The electric charge conveying is controlled by the starting or stop signal for being sent to charger/maintenance device 24.For example, microprocessor 94 can be with
It is configured to via state-of-charge indicator 20 to 24 sending signal of charger/maintenance device, to be based at least partially on battery 12
The charged current of state-of-charge, the state-of-charge of one or more battery battery core in battery battery core 54, the voltage of battery 12, electricity
The voltage of the one or more battery battery core in pond battery core 54, and/or any other suitable operational factor are starting or stoping
Electric charge flows.In one embodiment, battery management system 50 may be configured to the state-of-charge in response to determining battery 12
The voltage for having been maxed out state-of-charge threshold value or battery 12 has been maxed out voltage threshold and stops the electricity to battery 12
Lotus is flowed.Thus, battery management system 50 can protect battery battery core 54 to avoid overcharge.
Battery management system 50 can also pass through to monitor the operational factor of battery 12 and control defeated to the electric charge of battery 12
Send protection battery battery core 54 against damages.For example, battery management system 50 can monitor each battery electricity of charged battery 12
The state-of-charge and/or voltage of core 54 and the electric charge conveying to battery 12 is controlled to promote battery core to balance.These battery battery cores
54 may be with different rate discharges, and this may be strengthened by higher battery battery core temperature.As a result, these battery battery cores
54 are likely to be at different charge levels (for example, after electric discharge or inertia period).Although the battery battery core of parallel connection 54 can
With self-balancing to minimum voltage, but the battery battery core 54 of series connection may remain in different voltages.Therefore, in charging process
In, one or more battery battery core 54 may reach fullcharging electricity condition earlier than other battery battery cores 54 in array 52.To filling
The battery battery core 54 of full electricity carries out overcharge and may damage battery battery core 54.Accordingly, it may be desirable to be recover charge before
Stopping is charged and balances these battery battery cores 54.
Therefore, battery management system 50 can be configured to control to be adapted to the battery core balance for making the balance of battery battery core 54
System.Battery core balance system can be in 50 outside or inside of battery management system.In certain embodiments, battery management system 50
Balanced algorithm, the balanced algorithm can be applied to battery battery core 54 to select the battery battery core with highest charge level
(for example any battery battery core of state-of-charge or voltage, with minimum state-of-charge or voltage more than battery battery core).Institute
Selected battery battery core can be discharged by multiple parallel resistances, the state-of-charge until reaching the minimum battery battery core that charges.
Once battery battery core 54 is balanced, battery management system 50 can to 24 sending signal of charger/maintenance device with recover charge.Should
, it is noted that in certain embodiments, battery management system 50 can be configured in whole charging process with any suitable
Number of times balance these battery battery cores 54.Additionally, battery management system 50 (and miscellaneous part of battery 12) can be adapted to
Implement passive and/or active battery core balancing technique.For example, it is in passive equilibrium process, most from one or more chargings
The discharge energy of battery battery core can dissipate as heat.By contrast, during active balancing, energy can be from described one
Individual or multiple most battery battery cores that charge draw and are transferred to the minimum battery battery core of one or more chargings.For example, electricity
Pond management system 50 can include being adapted to energy is transferred to from most battery battery cores that charge the battery electricity for charging minimum
The dc-dc of core.Additionally, battery management system 50 can be adapted to implement continuous battery core balance.That is, battery
Management system 50 balances these battery battery cores 54 when can discharge during charging process and during use.
In addition, battery management system 50 can be configured to battery 12 is placed in sleep pattern to protect battery battery core 54 to exempt from
It is damaged.For example, battery management system 50 can be electronically controlled such as solid-state switch (for example, field-effect transistor (FET) or
Mos field effect transistor (MQSFET)) internal switch disconnection and closure, the internal switch can be with
It is placed with these terminals 16 in line.Disconnecting the solid-state switch will prevent electric current from flowing out from battery 12, and this will make electricity
Pond 12 is disconnected and battery 12 is placed in sleep pattern with vehicle 14.Especially, battery management system 50 can be configured to
Monitor one or more operational factors of battery 12 and/or battery battery core 54 and battery 12 can be placed in sleep pattern, with
Avoid over-discharge (for example, under-voltage), overvoltage (for example, in charging process), overheated or any other undesirable electricity
Pond situation.For example, as following reference picture 7 is more fully described, microprocessor 94 can be configured to by each battery electricity
Voltage and/or be compared with minimum voltage threshold by the voltage that voltmeter 100 is measured that the voltmeter 90 of core 54 is measured, and
Battery 12 can be placed in sleep pattern less than minimum voltage threshold in response to the voltage for determining battery 12 by battery management system 50,
To avoid the over-discharge of battery 12.In certain embodiments, minimum voltage threshold can be higher than for starting vehicle 14 most
Small voltage.In addition, microprocessor 94 can be configured to the temperature measured by the thermocouple 96 of each battery battery core 54 and/or by
The temperature of the measurement of thermocouple 104 is compared with maximum temperature threshold, and battery management system 50 can be in response to determining electricity
The temperature in pond 12 is more than maximum temperature threshold and forces battery 12 to enter sleep pattern.Additionally, battery management system 50 can be by
It is configured to battery 12 is placed in sleep pattern in response to the signal received from state-of-charge indicator 20.For example, state-of-charge
Indicator 20 can be with receiving user's input (for example, user can press the button of state-of-charge indicator 20) optionally compeling
Battery 12 is made to enter sleep pattern.If battery 12 will not be used within a period of time, what is may want to is to allow users to
Battery 12 is placed in into sleep pattern easily, to prevent the electric discharge of battery 12 or minimize electric discharge.In a sleep mode, can be with
Change operation, charging, electric discharge and/or the monitoring of battery.For example, can be electrolysed by making the input conductor and output conductor of battery
Coupling is avoiding further electric discharge.Similarly, some monitoring functions can stop or be placed on renewal basis less frequently
To save energy.However, in sleep pattern, can maintain to state-of-charge indicator (outside or be arranged on battery)
Some connections, to allow to restart (" wake-up ") battery and/or management system manually, for example, are opened by depressing instant contact
Close, as will be discussed.
In addition to monitoring and providing the feedback related to these operational factors, battery management system 50 can also be configured
The historical data of these operational factors is indicated for storage.In certain embodiments, battery management system 50 can be in memorizer 106
History (for example, record) of the middle storage with regard to exception.For example, memorizer 106 can store with when (or the battery battery core 54 of battery 12
One or more of) the related information of event when exceeding maximum predetermined threshold value of voltage, electric current and/or temperature.At some
In embodiment, memorizer 106 can also be stored and the voltage when battery 12 one or more of (or battery battery core 54), electric current
And/or the information that temperature is related less than event during minimum predetermined threshold.Memorizer 106 can be with storage running parameter (for example, electricity
Pressure, electric current and/or temperature) beyond predetermined threshold number of times counting.In certain embodiments, memorizer 106 can also be stored
The timestamp being associated with each event and/or persistent period.Additionally, memorizer 106 can be configured to store use information,
Such as maximum load, continuous working period in average load, battery 12 or the running status that can be used to monitor battery 12 its
His parameter.
What is may want to is exception record, to analyze the performance of battery 12.For example, the historical data can be used for afterwards
Analysis, manufaturing data, sales data, engineering design purpose are used for guaranteeing to keep in good repair, for example, determine and should send replacing battery still
Reimbursement.In order to access the historical data stored in memorizer 106, data input/output instrument 112 can be coupled to adapter
18 and can be from 106 downloading data of memorizer.Then, data input/output instrument 112 can analyze downloaded data or
Person can transfer data to processing meanss (such as computer) for analysis.In addition, data input/output instrument 112 can
To be configured to transfer data to battery management system 50 to be stored in memorizer 106.For example, data input/output
Instrument 112 can be with transmission data, such as predetermined threshold of these operational factors, the algorithm for calculating these operational factors, use
In the identification data or any other suitable information of battery 12.
Fig. 5 is the exploded view of battery 12, and its middle cover 62 removes to show battery management from the housing 60 of battery 12
The embodiment of system 50 and adapter 18.As illustrated, adapter 18 can be female pin connector.It should, however, be mentioned that
It is that in other embodiments, adapter 18 can be public connector and/or can be different types of adapter.Adapter 18
Including being adapted to be electrically coupled to one or more electric contacts of complementary connector (public pin connector), with AUI
Upper transmission signal and/or electric power.Especially, adapter 18 can be adapted to physically and electrically to be connected to state-of-charge and refer to
Show the adapter of device 20.Further, adapter 18 can be adapted to physically and electrically be connected to data input/output
Instrument 112.In order to realize the physically and electrically connection to state-of-charge indicator 20 and data input/output instrument 112, connection
Device 18 can include the shape (example of the adapter of the adapter with state-of-charge indicator 20 and data input/output instrument 112
Such as, size and geometry) and the complementary shape of pin arrangement and pin arrangement.
In certain embodiments, adapter 18 can include proprietary shape and pin arrangement.For example, adapter 18 can be
Keying.In one embodiment, the proprietary shape and pin arrangement can be selected so that adapter 18 is not coupled to except lotus
Any adapter outside electricity condition indicator 20 and data input/output instrument 112.
Additionally, adapter 18 can include any appropriate number of pin (for example, if adapter 18 is public connector)
Or socket contact (for example, if adapter 18 is female connectors).In certain embodiments, adapter 18 can include six or
Seven socket contacts 130.For example, adapter 18 can be included for the first socket contact 130 of data input and for data
Second socket contact 130 of output, these socket contacts can be adapted to the electricity for being connected to data input/output instrument 112
Contact or the electric contact of state-of-charge indicator 20.For example, the first socket contact 130 can be used for by data from data input/
Output instrument 112 downloads to the memorizer 106 of battery management system 50.In addition, the second socket contact 130 can be used for by with example
Outer related historical data is transferred to data input/output instrument 112 from memorizer 106.Adapter 18 can also include for
3rd socket contact 130 and the 4th socket contact 130 for electric power output of electric power input, these socket contacts can be fitted
It is made into the electric contact for being connected to state-of-charge indicator 20.
Additionally, adapter 18 can include the 5th socket contact 130 and the 6th socket contact 130, to activate state-of-charge
One or more display lamps (for example, LED) of indicator 20.For example, state-of-charge indicator 20 can include two display lamps,
Such as red led and green indicating lamp.If battery management system 50 determines that the state-of-charge of battery 12 is predetermined higher than one
Threshold value, then battery management system 50 can activate green indicating lamp using 130 sending signal of the 5th socket contact.Similarly,
If battery management system 50 determines that the state-of-charge of battery 12 is less than a predetermined threshold, battery management system 50 can make
With 130 sending signal of the 6th socket contact activating red led.These signal deletions disable can corresponding display lamp.
In addition, in certain embodiments, state-of-charge indicator can include the 3rd display lamp (for example, yellow led), and if electricity
Pond management system 50 determines the state-of-charge of battery in predetermined threshold range, and battery management system 50 can be by additional
Socket contact sending signal is activating yellow indicator lamp.In other embodiments, battery management system 50 can be inserted using the 5th
Seat contact 160 (or any other suitable socket contact) sends binary signal (for example, two or triad signal)
Optionally to activate the display lamp (for example, red, green and/or yellow indicator lamp) of state-of-charge indicator 20.For example, electricity
Pond management system 50 can send the first binary system for the green indicator for optionally activating state-of-charge indicator 20
Signal (for example, 001), the second binary signal of the yellow indicator for optionally activating state-of-charge indicator 20
(such as 010), and red indicator for optionally activating state-of-charge indicator 20 the 3rd binary signal (example
Such as, 100).In such embodiments, battery management system 50 can (or any other be suitable via the 6th socket contact 130
Socket contact) send electric power signal and powered with the display lamp of the chosen property activation to state-of-charge indicator 20.
In addition, adapter 18 can include being adapted to reception from the sleep mode signal of state-of-charge indicator 20
7th socket contact 130.It is to be understood, however, that adapter 18 can be included for data input, data output, instruction
Lamp control or the attaching socket contact 130 of any other signal.For example, in other embodiments, attaching socket contact can be used
In data input/output instrument 112 will be transferred to from memorizer 106 using data.
In addition, adapter 18 can meet the connection standard for providing high anti-intrusion protection class.Especially, adapter 18
These socket contacts can be protected from moist, dirt and chip in the position of shape and adapter 18.For example, adapter 18 can be with
It is recessed in the lid 62 of battery 12 so that lid 62 extends past adapter 18, and minimizes the exposure of adapter 18.Further
Ground, as illustrated, adapter 18 can be arranged by the side wall 132 around lid 62.Although adapter 18 can be disposed in lid 62
Other positions, but maybe advantageously adapter 18 is positioned on the sidepiece of lid 62, further to make adapter 18 minimum
Ground is exposed to moisture, dirt and the chip at the top that may contact battery cover 62.
Adapter 18 is electrically coupled to battery management system 50 via one or more leads 134.As illustrated, battery management
System 50 can be disposed between battery battery core 54 and the lid 62 of battery 12.Battery management system 50 can be disposed in support
On part 136, the support member can be coupled to housing 60 and/or lid 62.Therefore, support member 136 can include multiple attachments
Feature 138 (for example, screw) is being connected to housing 60 and/or lid 62 by support member 136.For example, support member 136 can couple
To the side wall 140 of housing 60.In one embodiment, support member 136 can be connected to the top 142 of these side walls 140.Should
, it is noted that being connected in some embodiments of housing 60 in support member 136, battery management system 50 is positioned in from battery electricity
At a certain distance from core 54 so that battery management system 50 does not contact battery battery core 54.Battery management system 50 is arranged in from electricity
Battery management system 50 can be conducive to protecting at a certain distance from pond battery core 54 from possible electrolyte leakage, overheated or pressure
Power.In addition, in certain embodiments, support member 136 and battery management system 50 can be disposed in by 140 He of roof of lid 62
In the internal chamber immediately below lid 62 that side wall 132 is formed.In such embodiments, support member 136 can be secured to lid
62 are fastened to housing 60, and are adapted to extend through the side wall 140 of housing 60.In other embodiments, support member 136
Can be integral with housing 60 or lid 62.However, battery management system 50 can be removed from battery 12.
Fig. 6 is the perspective view of the embodiment of exemplary state of charge indicator 20, the state-of-charge indicator include by
The adapter 160 (for example, multi-conductor connector) of the adapter 18 for being adapted to be connected to battery 12.Adapter 160 can be by can
Releasably connection (for example, tool-lessly removably coupling) is to the adapter 18 of battery 12.As illustrated, state-of-charge refers to
Show that device 20 can be connected to adapter 160 via lead 22.Lead 22 can increase the accessibility of state-of-charge indicator 20.Draw
Line 22 can be any suitable length.For example, the length of lead 22 can be between about one foot and five feet or about two
Between foot and four feet.In one embodiment, the length of lead 22 can be about three feet.
As illustrated, adapter 160 can be public pin connector.It should, however, be mentioned that in other embodiment
In, adapter 160 can be female connectors and/or can be different types of adapter.Adapter 160 can include being adapted
Into one or more electric contacts for being electrically coupled to adapter 18, with the transmission signal on AUI and/or electric power.Therefore,
Adapter 160 can include that the shape (for example, size and geometry) with the adapter 18 of battery 12 and pin arrangement are complementary
Shape and pin arrangement.In certain embodiments, adapter 160 can include proprietary shape and pin arrangement, for example, have
The proprietary shape and pin arrangement of high intrusion protection grade.
In addition, adapter 160 can include any appropriate number of pin (for example, if adapter 160 is public connection
Device) or socket contact (for example, if adapter 160 is female connectors).In certain embodiments, adapter 160 can include
Six, seven or eight pins.For example, adapter 160 can be included for electric power input, electric power output, data input, data
The pin of the control of sleep pattern switch in output, the control of display lamp and battery 12.Further, it is to be noted that one
In a little embodiments, the adapter 18 of battery 12 can be included than 160 more electric contacts of adapter.For example, adapter 18 can be with
Including being adapted to be connected to data input/output instrument 112 and be adapted to be not coupled to the electric contact of adapter 160.
However, adapter 160 still can be fully assembled on the adapter 18 of battery 12.
As illustrated, adapter 160 can include the first pin 164 for electric power input, first pin can be with
It is adapted to for electric power to be transferred to state-of-charge indicator 20 from battery 12.In certain embodiments, state-of-charge indicator 20
Can be adapted to using the electric power from battery 12 run.For example, state-of-charge indicator 20 can include can using
From one or more display lamps of the electric power of battery 12.As illustrated, state-of-charge indicator 20 include the first display lamp 166,
Second display lamp 168, and the 3rd display lamp 170.These display lamps can be LED, LCD, organic LED etc..In some enforcements
In example, the first display lamp 166 can be to provide the redness of the instruction of the state-of-charge low (for example, less than 10% full electricity) of battery 12
LED.State-of-charge indicator 20 can include the figure (such as alphabetical " E ") near the first display lamp 166, to provide the first finger
Show that lamp 166 represents the further instruction of low state-of-charge.Second display lamp can be to provide the state-of-charge of battery and delete (example
Such as, between 10% and 50% full electricity) instruction yellow or orange LED.In addition, the 3rd display lamp 170 can be to provide electricity
Almost expire the green LED of the instruction of electricity (for example, at least 50% charges) in pond.State-of-charge indicator 20 can be included near the 3rd
The figure (such as alphabetical " F ") of display lamp 170, to provide the further instruction that the 3rd display lamp represents fullcharging electricity condition.Should
It is noted that the merely exemplary offer of the state of charge percentage being associated with these display lamps, and in other embodiment
In can change.Further, in certain embodiments, state-of-charge indicator 20 can have two display lamps rather than three
It is individual.
As described above, these display lamps can be controlled to activate by battery management system 50 using binary system.In some realities
Apply in example, battery management system 50 can transfer signals to state-of-charge instruction by the second pin 172 of adapter 160
Device, optionally to activate the first display lamp 166, the second display lamp 168, or the 3rd display lamp 170.By way of example,
Battery management system 50 can be transmitted (for example, 001), to be used for for the first signal for optionally activating the first display lamp 166
Second binary signal of the second display lamp 168 is activated optionally (for example, 010), and for optionally activating the 3rd
3rd binary signal of display lamp 170 is (for example, 100).In other embodiments, battery management system 50 can pass through three
Pin transmits electric power signal, to activate the display lamp being associated with corresponding pin.For example, as described above, battery management system
50 can by the first pin transmit electric power signal with activate the first display lamp 166, by the second pin transmit electric power signal with
Activate the second display lamp 168, and by the 3rd pin transmit electric power signal to activate the 3rd display lamp 170.As described above, this
A little electric power signal disappearances disable can corresponding display lamp.
Although the embodiment for being shown is related to for providing the display lamp of the instruction of state-of-charge, it should be understood that
In other embodiments, state-of-charge indicator 20 can be adapted to provide the numeral instruction of state-of-charge, segmentation display (its
In show the percentage ratio of state-of-charge per segment table), single pointer (for example, LED or the figure of instruction for providing low state-of-charge
Shape), or any other suitable state-of-charge indicate.Further, it is to be noted that in other embodiments, state-of-charge refers to
Show that device 20 may be adapted to provide the letter related to other operational factors of battery (such as temperature, voltage and/or electric current)
Whether breath, the healthy related information to battery, and/or battery 12 are receiving the instruction of electric charge.
As it is indicated above, state-of-charge indicator 20 is battery management system 50 and battery charger/maintenance device 24
Between interface.Thus, state-of-charge indicator 20 is used as the entrance of charging system.As illustrated, state-of-charge indicator
20 are included for being connected to the second adapter 174 (for example, multi-conductor connector) of charger/maintenance device 24.Second adapter
174 bodies (as shown in the figure) that can be directly coupled to state-of-charge indicator 20, or can be connected to via lead charged
Positioning indicator 20.Adapter 174 can be any suitable adapter, such as male pin connector, female pin connector etc..
Adapter 174 can include being adapted to the first pin 176 and the second pin that receive the electric power from charger/maintenance device 24
178.In addition, in order to by power transmission to battery management system 50, adapter 160 can include for battery 12 is charged
Three pins 180 and four-limbed 182.As it is indicated above, battery management system 50 can be adapted to via state-of-charge
Data (for example, state-of-charge data) are transferred to charger/maintenance device 24 by indicator 20, and charger/maintenance device 24 can make
The electric charge of battery 12 is conveyed with the Data Control.Therefore, adapter 160 may include to be suitable to data input to receive from electricity
5th pin 184 of the data of pond management system 50, and adapter 178 can include being suitable to data output to be received
Additional pins of the data transfer to charger/maintenance device 24.It should, however, be mentioned that in certain embodiments, state-of-charge
Indicator can be configured to data are not transferred to charger/maintenance device 24 from battery management system 50, and therefore can be with
Do not include for promoting data transfer to the 5th pin 184 and additional pins of charger/maintenance device 24.
In addition, adapter 160 can include the 7th pin 186, the 7th pin is configured to battery management system
50 transmission signals are connected and force battery 12 to enter so that battery 12 is released from vehicle with controlling switch (for example, solid-state switch)
Enter sleep pattern.Specifically, in response to being manually pressed by the SR 190 of state-of-charge indicator 20, can be by signal from lotus
Electricity condition indicator 20 is transferred to battery management system 50.In the summer electric power motion during use, such as do not deposited in the winter time
Vehicle, forces battery 12 be conducive to making the electric discharge of battery 12 to minimize into sleep pattern using SR 190.Separately
Outward, SR 190 can be used as anti-theft device by battery 12 is released connection from vehicle 14.In certain embodiments,
After SR 190 has pressed predetermined time amount, signal can be transferred to battery from state-of-charge indicator 20
Management system 50.For example, state-of-charge indicator 20 can be adapted to SR 190 be pressed 2 seconds, 3 seconds, 4
Sending signal after second, 5 seconds or any other suitable time quantum.
SR 190 can be also used for reactivating battery 12.For example, when battery is in sleep pattern, press multiple
Position button 190 may cause to state-of-charge indicator 20 to 50 transmission signal of battery management system with controlling switch by 12 weight of battery
Vehicle 14 is connected to newly.In certain embodiments, after SR 190 has pressed predetermined time amount, can be by weight
New activation signal is transferred to battery management system 50 from state-of-charge indicator 20.The predetermined time amount can with for by electricity
Pond 12 is identical or different from the predetermined time amount that vehicle releases connection.For example, state-of-charge indicator 20 can be adapted to
SR 190 be pressed 2 seconds, 3 seconds, 4 seconds, 5 seconds or any other suitable time quantum after transmission reactivate letter
Number.
Although the embodiment for being shown is related to the SR that can be pressed, in other embodiments, SR
190 can be slide switches or the on/off control bar for being adapted to move between on-state and off-state.At this
In the embodiment of sample, state-of-charge indicator 20 can be adapted to it is described switch or control-rod be transformed into from on-state it is disconnected
Immediately to 50 transmission signal of battery management system after open state (or vice versa as the same), or can be adapted in the scheduled time
Transmission signal after amount.It will be further noted that, SR 190 can be disposed in state-of-charge indicator 20
Any suitable position.
Fig. 7 is to describe the example logic controlled by the sleep pattern for battery 12 that battery management system 50 is performed
200 flow chart.As it is indicated above, battery management system 50 can be configured to monitor battery 12 to determine battery 12 being
It is no to be placed in sleep pattern to protect battery 12.For example, battery management system 50 can be adapted to analyze battery 12
One or more operational factors, to prevent overdischarge (for example, under-voltage), overvoltage (for example, during the charging phase), excessively electric
Stream is (for example, in charging process), overtemperature or any other undesirable battery condition.Further, battery management system 50
User input can be configured to respond to battery 12 is placed in into sleep pattern.
As illustrated, battery management system 50 can monitor the signal (frame 202) that one or more receive.It is one
Or multiple signals for receiving can be from the signal of one or more sensors that is arranged in battery 12.For example, these
The signal for receiving can be by the voltmeter 90 of each battery battery core 54, the thermocouple 96 of each battery battery core 54, each battery
The ammeter 98 of battery core 54, the voltmeter 100 of battery management system 50, the ammeter 102, battery management of battery management system 50
The thermocouple 104 of system 50, be adapted to measure from charger/maintenance device 24 input voltage voltmeter, be adapted to
Measure the generation such as the ammeter of input current from charger/maintenance device 24.As detailed above, microprocessor 94
The multiple operational factors (for example, voltage, electric current, temperature etc.) based on these signal of change batteries 12 can be configured to.In addition,
Battery management system 50 can receive one or more of the microprocessor 92 of the measurement apparatus 64 from each battery battery core 54
Signal, and the signal can include the operational factor that calculates for corresponding battery battery core 54.Further, cell tube
Reason system 50 can receive the signal from state-of-charge indicator 20 in response to pressing SR 190.
As indicated in a block 204, battery management system 50 can be configured to determine whether to have been received by being placed in battery 12
The user input of sleep pattern.For example, if battery 12 is activity and is connected to vehicle 14, and battery management system 50 connects
The signal (for example, by the 7th pin 186 transmit) from state-of-charge adapter 20 is received, then battery management system 50 can be with
It is determined that having been received by battery 12 is placed in the user input of sleep pattern.Accordingly, in response to the user input, battery management
System 50 can force battery 12 to enter sleep pattern (frame 206).In certain embodiments, battery management system 50 can be with electronics
Ground control such as solid-state switch (for example, field-effect transistor (FET) or mos field effect transistor
(MOSFET) battery 12 is placed in sleep pattern by the disconnection of internal switch) and closure.In such embodiments, disconnect
The switch will prevent electric current from flowing out from battery 12, so as to battery 12 being released connection from vehicle 14 and battery 12 being placed in sleep
Pattern.
If battery management system 50 is not received by the user input that battery is placed in sleep pattern, battery management system
System 50 can continue to monitor and analyze these signals for receiving, to determine whether battery 12 to be placed in sleep pattern.Example
Such as, whether battery management system 50 can determine the state-of-charge of battery 12 less than predetermined threshold (frame 208).As described above, can
The state-of-charge of battery 12 is determined with based on the voltage of battery 12, electric current, and/or temperature.Additionally or alternatively, cell tube
Whether reason system 50 can determine the depth of discharge of battery more than predetermined discharge depth threshold.Additionally, in certain embodiments, electricity
The voltage in pond can serve as the approximation of the state-of-charge of battery.In certain embodiments, the predetermined threshold can at least portion
Divide these parameters of ground based on battery 12 and for starting the minimum charged of vehicle 14.For example, if vehicle 14 needs at least 11
Lie prostrate to start, then the predetermined threshold can be at least 11 volts.In certain embodiments, the predetermined threshold can be about 11.3
Volt.Thus, battery 12 can have be enough to start vehicle 14 and to the power supply a period of time of vehicle 14 until battery 12 from charger/
Maintenance device 24 receives the carrying capacity of electric charge.If battery management system 50 determines that the state-of-charge of battery 12 is predetermined less than described
Threshold value, then battery management system 50 can force battery 12 enter sleep pattern (frame 206) with prevent over-discharge (for example, owe
Voltage).
In addition, battery management system 50 can be adapted to battery 12 is protected in charging process.For example, battery management system
Whether system 50 is can determine from charger/maintenance device to the input voltage of battery 12 more than predetermined threshold (frame 210).If battery
Management system 50 determines the input voltage to battery 12 more than the predetermined threshold, and battery management system 50 can force battery 12
Into sleep pattern (frame 206) with prevent be input into overvoltage.Similarly, battery management system 50 is can determine from charger/dimension
Whether shield device is more than predetermined threshold (frame 212) to the input current of battery 12.If battery management system 50 is determined to battery 12
Input current be more than the predetermined threshold, battery management system 50 can force battery 12 enter sleep pattern (frame 206) with
Prevent from being input into overcurrent.It should be pointed out that input voltage and input current can be selected based on these parameters of battery 12
Predetermined threshold.
Additionally, the temperature that battery management system 50 can be configured to monitor battery 12 is overheated to prevent.For example, cell tube
Whether reason system 50 can determine the temperature of battery 12 more than predetermined threshold (frame 214).As it is indicated above, can be using heat
The thermocouple 96 of galvanic couple 104 and/or one or more battery battery core 54 is determining the temperature of battery 12.If battery management system
50 determine that the temperature of battery 12 is more than the predetermined threshold, and battery management system 50 can force battery 12 to enter sleep pattern
(frame 206) is overheated to prevent.In addition, battery management system 50 can determine of the temperature of battery 12 and/or battery 12 or
Whether the temperature of multiple battery battery cores 54 is less than predetermined threshold (frame 216).In some embodiments, it may be desirable to battery management system
System 50 monitors the temperature of the temperature and/or one or more battery battery core 54 of battery 12 in charging process, because when temperature is low
Battery 12 is charged when predetermined temperature and may damage battery battery core 54.For example, when battery temperature be less than zero degrees Fahrenheit when pair
Some lithium cell chargings may damage battery battery core.Therefore, if 50 temperature of battery management system is less than predetermined threshold,
Battery management system 50 can force battery to enter sleep pattern (frame 206) to prevent the damage to battery battery core from (for example, filling
In electric process).
Further, it is to be noted that in certain embodiments, battery management system 50 can be configured to consider operation ginseng
Several combinations is determining whether for battery 12 to be converted to sleep pattern (frame 206).In certain embodiments, if two or more
Individual operational factor (for example, temperature, state-of-charge, depth of discharge, input voltage, input current etc.) violates corresponding predetermined threshold
Value, then battery 12 can be converted to sleep pattern by battery management system 50.By way of example, if battery temperature is
110 degrees Fahrenheits, and every other operational factor does not violate corresponding predetermined threshold, then and battery management system 50 can not be by electricity
Pond 12 is converted to sleep pattern.In addition, if voltage is 14.8 volts, and every other operational factor does not violate corresponding predetermined
Threshold value, then battery management system 50 battery 12 can not be converted to sleep pattern.If however, battery temperature is 110 Fahrenheits
Spend and voltage is 14.8 volts, then battery management system 50 can be by cells convert to sleep pattern.
As it is indicated above, the SR 190 of state-of-charge indicator 20 can be also used for reactivating battery 12.
Fig. 8 is the flow chart for describing the example logic 230 for reactivating for battery 12 performed by battery management system 50.Such as
Shown in figure, battery management system 50 can receive signal from state-of-charge indicator 20 to reactivate 12 (frame of battery
232).As it is indicated above, the SR 190 for pressing state-of-charge indicator 20 can be generated and cause battery management system
The signal of the state (for example, from be disconnected to closure or vice versa) of 50 change internal switches.Therefore, if battery 12 is in sleep mould
Formula, the then signal for receiving may cause to 50 closure switch of battery management system and reactivate battery 12 (frame 234).
In certain embodiments, the shape for causing battery management system 50 that battery 12 is placed in sleep pattern can be detected
Condition, such as under-voltage, input overvoltage, input overcurrent or overheated.When battery 12 is reactivated, this situation can be with
Yet suffer from.Therefore, battery management system 50 can implement sleep pattern control logic 200, to reactivate it in battery 12
Continue the operational factor of monitoring battery 12 afterwards and protect battery 12 to avoid undesirable operation conditions.If thus, in electricity
Pond 12 be placed in sleep pattern and and then after reactivating, the situation (for example, under-voltage, input overvoltage, be input into
Electric current or overtemperature) yet suffer from, then battery management system 50 can make battery 12 return to sleep pattern to avoid damaging battery 12.
Although having had shown and described only some features and the embodiment of the disclosure, those skilled in the art can be with
Make many modifications and variations (for example, the size of different elements, size, structure, shape and ratio, parameter (for example, temperature, pressure
Power etc.) value, materials'use, color, the change of the aspect such as orientation), and substantially without departing from the theme described in claim
Novel teachings and advantage.Can be changed according to the order or sequence of alternate embodiment, any process or method and step or again
Sequence.It is understood, therefore, that claims are intended to fall in the true spirit of disclosed embodiment
All such modifications and variations.Additionally, in order to provide the simple and clear description to embodiment, may not describe actual embodiment
All features (that is, unrelated with the best mode of the execution disclosed embodiment for contemplating at present feature, or with realize institute
The unrelated feature of the open embodiment of opinion).It should be appreciated that in the development process of any such actual embodiment
In, such as in any engineering or design object, the specific decision-making of substantial amounts of enforcement can be made.Such development is probably
It is complicated and time-consuming, but for those those of ordinary skill for enjoying disclosure benefit, this be only design, manufacture and
The routine mission of production and without the need for excessively testing.
Claims (27)
1. a kind of method for managing battery module, including:
Receive the data related to one or more operational factors of the battery module;
Determine whether the first operational factor in one or more of operational factors violates first threshold;And
In response to determining that first operational factor violates the first threshold, the battery module is changed into from operational mode
Sleep pattern.
2. the method for claim 1, wherein first operational factor includes the temperature of the battery module.
3. the method for claim 1, wherein first operational factor includes the depth of discharge of the battery module.
4. the method for claim 1, wherein first operational factor includes that the battery module is connect from charging device
The input current or input voltage of receipts.
5. the method for claim 1, including:
Determine whether the second operational factor in one or more of operational factors is less than Second Threshold;And
In response to determining that second operational factor is less than the Second Threshold, the battery module is changed into from operational mode
Sleep pattern.
6. method as claimed in claim 5, wherein, second operational factor includes the state-of-charge of the battery module.
7. the method for claim 1, wherein receive related to one or more operational factors of the battery module
Data include:
Signal is received from the sensor being arranged in the battery module, wherein, the sensor is configured to measure the electricity
The operational factor of pond module;And
It is at least partially based on the value that the signal determines the operational factor.
8. method as claimed in claim 7, wherein, the sensor includes thermocouple, voltmeter or ammeter.
9. the method for claim 1, wherein the battery module includes battery battery core array, and wherein, receive with
The data that one or more operational factors of shown battery module are related include:
Number is received from the sensor being arranged in the battery module and be associated with the battery battery core (54) in the array
According to, wherein, the sensor is configured to the operational factor for measuring the battery battery core (54);And
It is at least partially based on the value that the signal determines the operational factor.
10. the method for claim 1, wherein the battery module includes battery battery core array, and wherein, receives
The data related to one or more operational factors of shown battery module include:
From the sensor receiving data being arranged in the battery module and be associated with the battery battery core array, wherein,
The sensor is configured to the operational factor for measuring the battery battery core array;And
It is at least partially based on the value that the signal determines the operational factor.
The method of claim 1, wherein 11. determine the first operational factor in one or more of operational factors
Whether include more than first threshold:
The memorizer of the battery module is accessed to determine the first threshold;And by the operational factor and first threshold
Value is compared.
12. the method for claim 1, including:
Signal is received from the state-of-charge indicator that the battery module is connected in outside, wherein, the state-of-charge is indicated
Device is configured to respond to the state change of the reset switch being arranged in the state-of-charge indicator and sends the signal
To the battery module;And
In response to the signal from the state-of-charge indicator, the battery module is changed into into sleep mould from operational mode
Formula.
13. the method for claim 1, including:
Signal is received from the state-of-charge indicator for being connected to the battery module, wherein, the state-of-charge indicator is matched somebody with somebody
The signal is sent by the state change for being set to the reset switch in response to being arranged on the housing of the state-of-charge indicator
To the battery module;And
If the battery module is in sleep pattern, in response to received signal, by the battery module from sleep
Mode change is operational mode.
The method of claim 1, wherein the battery module is changed into operational mode from sleep pattern by 14. includes
Control the internal switch of the battery module.
15. methods as claimed in claim 14, including:
Signal is received from the state-of-charge indicator for being connected to the battery module, wherein, the state-of-charge indicator is matched somebody with somebody
The signal is sent by the state change for being set to the reset switch in response to being arranged on the housing of the state-of-charge indicator
To the battery module;
If the internal switch closure, the internal switch of the battery module is made to break in response to received signal
Open;And
If the internal switch disconnects, close the internal switch of the battery module in response to received signal
Close.
A kind of 16. systems, including:
Battery management system, during the battery management system is arranged in the housing of battery module and is configured to:
Analyze one or more operational factors of the battery module;And
The analysis of the one or more of operational factors to the battery module is at least partially based on, the battery module is existed
Change between operational mode and sleep pattern.
17. systems according to claim 16, including the internal switch for being electrically coupled to the battery management system, and its
In, the battery management system is configured to make the battery system in operational mode and sleep pattern via the internal switch
Between change.
18. systems according to claim 16, wherein, the battery management system is configured to:
Each operational factor in one or more of operational factors is compared with respective threshold;And
In response to determining that at least one of one or more of operational factors operational factor is more than its respective threshold, make described
Battery system is changed into sleep pattern from operational mode.
19. systems as claimed in claim 18, wherein, the battery management system include being configured to storage it is one or
The memorizer of the threshold value of each operational factor in multiple operational factors.
20. systems as claimed in claim 16, including one or more sensors for being electrically coupled to the battery management system,
Wherein, each sensor is configurable to generate the operational factor in the one or more of operational factors with shown battery module
Related signal, and wherein, the battery management system includes being configured to be at least partially based on one or more of biographies
The signal that sensor is generated determines the processor of one or more of operational factors of the battery module.
21. systems as claimed in claim 16, including the instruction of the state-of-charge for being configured to supply the battery module
State-of-charge indicator, wherein, the state-of-charge indicator is configured to be connected to and is arranged in the described of the battery module
Multi-conductor connector on the outer surface of housing, and wherein, the state-of-charge indicator includes being configured to connecting shape
The reset switch of sex reversal is selected between state and off state.
22. systems as claimed in claim 21, wherein, the state-of-charge indicator is configured to respond to the reset and opens
The state change of pass transmits a signal to the battery management system via the multi-conductor connector of the battery module, and
And wherein, the battery management system be configured to respond to received signal make the battery module operational mode with
Change between sleep pattern.
23. the system as claimed in claim 22, wherein, the battery management system is configured to:
If the battery module is in operational mode, in response to received signal, by the battery module from operation
Mode change is sleep pattern;And
If the battery module is in sleep pattern, in response to received signal, by the battery module from sleep
Mode change is operational mode.
A kind of 24. systems, including:
Battery module, the battery module include the battery management system being arranged in the housing (60) of the battery module;With
And
It is configured to be attached to the state-of-charge indicator of the battery module, wherein, the state-of-charge indicator includes cloth
The manual operation switch on the housing of the state-of-charge indicator is put, wherein, the switch is configured in on-state
Change between off state, and wherein, the state-of-charge indicator is configured to respond to the state of the switch and becomes
Change transmits a signal to the battery management system;And
Wherein, the battery management system is configured to respond to received signal and makes the battery module in operational mode
Change between sleep pattern.
25. systems as claimed in claim 24, wherein, the battery module includes internal switch, and wherein, the battery
Management system is configured to:
If the inside is disconnected by the internal switch closure in response to received signal;And
If the internal switch disconnects, the internal switch closure is made in response to received signal.
26. systems according to claim 24, wherein, the battery management system is configured to:
Monitor the operational factor of the battery module;
The operational factor and threshold value are compared;And
In response to determining that the operational factor violates the threshold value, the battery module is changed into into sleep mould from operational mode
Formula.
27. systems according to claim 26, wherein, the operational factor includes the temperature of the battery module and described
The depth of discharge of battery module.
Applications Claiming Priority (3)
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US14/266,587 | 2014-04-30 | ||
US14/266,587 US9692240B2 (en) | 2014-04-30 | 2014-04-30 | Battery sleep mode management method and system |
PCT/US2015/026999 WO2015167889A1 (en) | 2014-04-30 | 2015-04-22 | Battery sleep mode management method and system |
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CN106663843A true CN106663843A (en) | 2017-05-10 |
CN106663843B CN106663843B (en) | 2022-06-21 |
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US (1) | US9692240B2 (en) |
EP (1) | EP3137916B1 (en) |
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Also Published As
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CN106663843B (en) | 2022-06-21 |
EP3137916A1 (en) | 2017-03-08 |
EP3137916B1 (en) | 2022-11-02 |
US9692240B2 (en) | 2017-06-27 |
WO2015167889A1 (en) | 2015-11-05 |
US20150318723A1 (en) | 2015-11-05 |
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